Drain-induced barrier lowering

About: Drain-induced barrier lowering is a research topic. Over the lifetime, 6163 publications have been published within this topic receiving 101547 citations.

Silicon carbide field effect device

Abstract: A silicon carbide field effect device includes vertically stacked silicon carbide regions of first conductivity type, extending from a lowermost drain region to an uppermost source region. In between the drain and source regions, a drift region and a channel region are provided. The drift region extends adjacent the drain region and the channel region extends between the drift region and the source region. Control of majority carrier conduction between the source and drain regions is provided by a plurality of trenches, which extend through the source and channel region, and conductive gate electrodes therein. To provide high blocking voltage capability and low on-state resistance, the doping concentration in the drift region is selected to be greater than the doping concentration of the channel region but below the doping concentration of the drain and source regions. Preferably, the material used for the gate electrodes, the spacing between adjacent trenches and the doping concentration of the channel region are chosen so that the channel region is depleted of majority charge carriers when zero potential bias is applied to the gate electrodes.

PMOS memory cell with hot electron injection programming and tunnelling erasing

Abstract: A P-channel MOS memory cell has P+ source and drain regions formed in an N-well. A thin tunnel oxide is provided between the well surface and an overlying floating gate. In one embodiment, the thin tunnel oxide extends over a substantial portion of the active region and the device. An overlying control gate is insulated from the floating gate by an insulating layer. The device is programmed via hot electron injection from the drain end of the channel region to the floating gate, without avalanche breakdown, which allows the cell to be bit-selectable during programming. Erasing is accomplished by electron tunneling from the floating gate to the N-well with the source, drain, and N-well regions equally biased. Since there is no high drain/well junction bias voltage, the channel length of the cell may be reduced without incurring and destructive junction stress.

Split-gate field effect transistor

Abstract: A field effect transistor having a gate voltage swing in the transistor channel varying as a function of position between the drain and the source. The gate voltage swing in the transistor channel may be made to vary as a function of position by making the threshold voltage a function of position. Alternatively, a split-gate device may be used by applying a voltage between the gates. In both cases, the electric field near the source is raised to accelerate the electrons thereby decreasing electron transit time.

PMOS flash EEPROM cell with single poly

Abstract: A P-channel single-poly EPROM cell has P+ source and P+ drain regions, and a channel extending therebetween, formed in an N-type well. A thin layer of tunnel oxide is provided over the channel and, in some embodiments, over significant portions of P+ source and P+ drain regions. A poly-silicon floating gate overlies the tunnel oxide. A P diffusion region is formed in a portion of the N-well underlying the floating gate and is thereby capacitively coupled to the floating gate. In this manner, the P diffusion region serves as a control gate for the memory cell. Programming is accomplished by coupling a sufficient voltage to the floating gate via the control gate while biasing the source and drain regions to cause the hot injection of electrons from the N-well/drain junction to the floating gate, while erasing is realized by biasing the floating gate, N-well, source and drain regions appropriately so as cause the tunneling of electrons from the floating gate to the N-well, the source, and the drain. In another embodiment, an N-type diffusion region is formed within the P diffusion region and serves as the control gate.

Thin film transistors with vertically offset drain regions

Abstract: There is provided a semiconductor device, such as a TFT, with a vertical drain offset region. The device contains a substrate having an upper first surface, a semiconductor channel region of a first conductivity type over the first surface, a gate electrode and a gate insulating layer between the gate electrode and the channel region. The device also contains a heavily doped semiconductor source region of a second conductivity type, a heavily doped semiconductor drain region of a second conductivity type. An intrinsic or lightly doped semiconductor drain offset region is located between the drain region and the channel region, such that the drain region is offset from the channel region at least partially in a direction perpendicular to the first surface.